In vitro evaluation of antioxidant properties of Rosa roxburghii plant extract / Catharina Scholtz Janse van Rensburg

Janse van Rensburg, Catharina Scholtz

January 2003

Rosa roxburghii, also known as "Burr Rose" or "Chestnut Rose", originated in southwest China and was introduced to the botanic garden in Calcutta around 1824. It was named after William Roxburgh who was the superintendent. The extract of fruit of the Rosa roxburghii plant is the base ingredient of a range of products that is commercially sold under the Cili Bao label. The extract is composed of a wide range of substances of nutritional value, in particular a relatively high amount of antioxidants such as ascorbate and plant phenols. It has been reported before that supplementation with the fruit extract resulted in increased red blood cell superoxide dismutase, catalase and the reduced form of glutathione. An enhancement of the antioxidant status could contribute to the protection against several diseases where oxidative stress is a major factor in the pathology, such as atherosclerosis, cancer and immunity stress. Several anecdotal reports with little (published) scientific support claim that human supplementation of the Rosa roxburghii extract to the diet has a protective effect against several diseases, including the above mentioned. Medicinal and herbal plants are used in large sections in developing countries for primary care and there is now also an increase in the use of natural therapies in developed countries. However, plant extracts can also consist of anti-nutritional and possible toxic components, such as oxalic acid and nitrates, which could express cytotoxic and genotoxic activities. Therefore, understanding the health benefits but also the potential toxicity of these plants is important. The objective of this study was to investigate the beneficial properties of Rosa roxburghii extract from an antioxidant potential perspective and in particular to investigate the safety of the product for human consumption. For this purpose in vitro evaluation of the cellular toxicity, mutagenicity and genotoxicity was performed. In addition, specific biochemical parameters relating to the antioxidant status of the product, i.e. antioxidant capacity, oxidative stress prevention and glutathione redox state profiles were investigated in vitro as well as in vivo. The results indicated that Rosa Roxburghii fruit extract was not mutagenic when tested with Salmonella typhimurium strains TA 98, TA 100 and TA 102 in the Ames test. The results, however, pointed towards an antimutagenic effect of the extract in these strains against metabolic activated mutagens 2- acetylaminoflurorene (2-AAF) and aflatoxin B1, and the direct-acting mutagen, methanesulfonate (MMS). In primary rat hepatocyte, Rosa roxbughii extract did not elicit double or single strand DNA damage and cell viability loss using the single cell gel electrophoresis (Comet assay), lactate dehydrogenase leakage test or the mitochondria1 conversion test of MTT to formazan (MTT test). Again the opposite effect was observed: pre-treatment of hepatocytes with Rosa roxbughii extract significantly reduced the effect of oxidative stress-induced cellular- and genotoxicity. These results point to a protective effect against oxidative stress which is reflected in an increase of the antioxidant capacity and glutathione redox state (GSH/GSSG) in vitro (lymphoblasts) and in vivo (humans) reported in this study. This study underlines the previously suggested potential of this plant extract as a natural and safe antioxidant supplement. / Thesis (M.Sc. (Biochemistry))--North-West University, Potchefstroom Campus, 2004.

Rosa roxburghii

Antioxidant capacity

Mutagenicity

Genotoxicity

Cytotoxiciti

In vitro evaluation of antioxidant properties of Rosa roxburghii plant extract / Catharina Scholtz Janse van Rensburg

Janse van Rensburg, Catharina Scholtz

January 2003

Rosa roxburghii, also known as "Burr Rose" or "Chestnut Rose", originated in southwest China and was introduced to the botanic garden in Calcutta around 1824. It was named after William Roxburgh who was the superintendent. The extract of fruit of the Rosa roxburghii plant is the base ingredient of a range of products that is commercially sold under the Cili Bao label. The extract is composed of a wide range of substances of nutritional value, in particular a relatively high amount of antioxidants such as ascorbate and plant phenols. It has been reported before that supplementation with the fruit extract resulted in increased red blood cell superoxide dismutase, catalase and the reduced form of glutathione. An enhancement of the antioxidant status could contribute to the protection against several diseases where oxidative stress is a major factor in the pathology, such as atherosclerosis, cancer and immunity stress. Several anecdotal reports with little (published) scientific support claim that human supplementation of the Rosa roxburghii extract to the diet has a protective effect against several diseases, including the above mentioned. Medicinal and herbal plants are used in large sections in developing countries for primary care and there is now also an increase in the use of natural therapies in developed countries. However, plant extracts can also consist of anti-nutritional and possible toxic components, such as oxalic acid and nitrates, which could express cytotoxic and genotoxic activities. Therefore, understanding the health benefits but also the potential toxicity of these plants is important. The objective of this study was to investigate the beneficial properties of Rosa roxburghii extract from an antioxidant potential perspective and in particular to investigate the safety of the product for human consumption. For this purpose in vitro evaluation of the cellular toxicity, mutagenicity and genotoxicity was performed. In addition, specific biochemical parameters relating to the antioxidant status of the product, i.e. antioxidant capacity, oxidative stress prevention and glutathione redox state profiles were investigated in vitro as well as in vivo. The results indicated that Rosa Roxburghii fruit extract was not mutagenic when tested with Salmonella typhimurium strains TA 98, TA 100 and TA 102 in the Ames test. The results, however, pointed towards an antimutagenic effect of the extract in these strains against metabolic activated mutagens 2- acetylaminoflurorene (2-AAF) and aflatoxin B1, and the direct-acting mutagen, methanesulfonate (MMS). In primary rat hepatocyte, Rosa roxbughii extract did not elicit double or single strand DNA damage and cell viability loss using the single cell gel electrophoresis (Comet assay), lactate dehydrogenase leakage test or the mitochondria1 conversion test of MTT to formazan (MTT test). Again the opposite effect was observed: pre-treatment of hepatocytes with Rosa roxbughii extract significantly reduced the effect of oxidative stress-induced cellular- and genotoxicity. These results point to a protective effect against oxidative stress which is reflected in an increase of the antioxidant capacity and glutathione redox state (GSH/GSSG) in vitro (lymphoblasts) and in vivo (humans) reported in this study. This study underlines the previously suggested potential of this plant extract as a natural and safe antioxidant supplement. / Thesis (M.Sc. (Biochemistry))--North-West University, Potchefstroom Campus, 2004.

Rosa roxburghii

Antioxidant capacity

Mutagenicity

Genotoxicity

Cytotoxiciti

Desenvolvimento e aplicação de um novo ensaio para a determinação eletroquímica da capacidade antioxidante de compostos modelo e de matrizes complexas / Development and application of a new assay for the electrochemical determination of the antioxidant capacity of model compounds and of complex matrices

Ferreira, Rafael de Queiroz

22 July 2009

Este trabalho descreve o desenvolvimento e aplicações práticas de uma nova e simples metodologia eletroquímica para a determinação da capacidade antioxidante de moléculas modelo específicas e/ou algumas amostras complexas de alimentos normalmente consumidas no Brasil. Outros sistemas de interesse teórico ou tecnológico também foram investigados. O método se baseia no uso de uma quantidade conhecida de um íon inorgânico como oxidante e na determinação cronoamperométrica de sua concentração remanescente após reação com as espécies antioxidantes de interesse. Contudo, testes iniciais para diferentes marcas comerciais de sucos de laranjas usando Fe3+ como oxidante (ensaio FRAP modificado), só obtiveram êxito quando o antioxidante apresenta um comportamento eletroquímico totalmente irreversível como, por exemplo, o ácido ascórbico. Para superar esse problema, o ensaio foi então desenvolvido usando o Ce4+ como oxidante (ensaio CRAC) uma vez que sua redução após reação pode ser realizada em 0,8 V vs Ag/AgCl, uma região de potencial na qual não ocorre a redução das espécies formadas pela oxidação reversível ou quase reversível do antioxidante. Devido ao elevado potencial anódico requerido quando o Ce4+ é usado, foi necessário um filme de diamante dopado com boro como eletrodo de trabalho. Após uma rigorosa caracterização do sistema eletroquímico, foram realizadas determinações da capacidade antioxidante de oito compostos padrões (ácido ascórbico, ácido gálico, ácido tânico, BHA, catequina, quercetina, rutina e trolox), usando o ensaio CRAC. Os resultados mostraram uma correlação satisfatória com ensaios mais complexos reportados na literatura e foram aplicados em um conjunto de sucos de frutas industrializados, mostrando valores máximos com quase uma ordem de grandeza superior ao apresentado pelo composto de referência (trolox), com a seguinte seqüência de capacidade antioxidante: caju > goiaba > uva > manga > laranja > maracujá. Considerando a busca da indústria local de \"cachaça\" por madeiras alternativas em contrapartida aos tonéis de carvalho, o ensaio CRAC foi realizado usando quatro extratos etanólicos de madeiras brasileiras [Pequi (Caryocar brasiliense), Imbuia (Octea porosa), Cabreúva (Myrocarpus frondosus) e Cabreúva-vermelha (Myroxylon balsamum)] assim como um extrato de Carvalho (Quercus sp), para comparação. Os resultados indicaram um aumento na capacidade antioxidante na ordem apresentada acima e, apesar da melhor amostra (Cabreúva-vermelha) ter apenas 60% da capacidade antioxidante apresentada pelo carvalho, sua disponibilidade e preço despertam o interesse por pesquisas futuras. Uma avaliação comparativa dos resultados obtidos usando os ensaios CRAC e DPPH foi realizado para extratos metanólicos de cana-de-açúcar e polpa de maracujá. Essa comparação revelou uma diferença quantitativa entre os valores dos ensaios, porém, a hierarquia foi mantida para cada conjunto de resultado. Esse efeito foi atribuído às diferenças nos mecanismos dominantes para a desativação radicalar, bem como para as condições experimentais de cada ensaio. A correlação entre a estrutura e a atividade antioxidante de moléculas modelo de flavonóides sob investigação foi relatada devido à presença de certos grupos substituintes na estrutura de difenilpirano. A atividade hierárquica para tais grupos foi estabelecida como: OH(C2´C4´) > OH(C4´) ~ OH(C3´C4´) > C2=C3 + 4-oxo > OH(C3,C5) + 4-oxo > OH(C3) + 4-oxo > OH(C5) + 4-oxo > OH(C3,C5). A formação de complexos entre flavonóides e íons metálicos, tal como o Fe2+, tem um forte efeito sobre a capacidade antioxidante e o ensaio CRAC mostrou que para a morina, quercetina e fisetina, esse aumento foi de 15,3; 31,8 e 27,9%, respectivamente. Por outro lado, para a catequina e crisina, o aumento foi de apenas 1,8 e 7,8%, respectivamente. Esses aumentos foram relatados devido à presença de, pelo menos, um dos três tipos de sítios ativos na molécula polifenólica que interage com íons metálicos. Todos esses resultados confirmam que o ensaio CRAC é uma ferramenta simples e viável para a determinação da capacidade antioxidante de uma variedade de sistemas práticos e moléculas modelo. / This work describes the development and practical applications of a novel and simple electrochemical methodology for the determination of the antioxidant capacity of specific model molecules and/or some complex food samples currently consumed in Brazil. Other systems having either theoretical or technological interest were also investigated. The method is based on the use of a known amount of an inorganic ion as the oxidant and in the chronoamperometric determination of its remaining concentration after reaction with the chosen antioxidant species. However, initial tests for different commercial brands of orange juices using Fe3+ as the oxidant (modified FRAP assay) were only successful when the antioxidant has a totally irreversible electrochemical behavior as, for example, ascorbic acid. To overcome this problem, the assays were then performed using Ce4+ as the oxidant (the CRAC assay) since its reduction after reaction can be carried out at 0.8 V vs Ag/AgCl, a potential region where the reduction of species formed by the reversible or quasi-reversible oxidation of the antioxidant does not occur. Due to the high anodic potentials required when using Ce4+, it was necessary to have a boron-doped diamond film as the working electrode. After a rigorous characterization of the electrochemical systems, measurements of the antioxidant capacity of eight standard compounds (ascorbic acid, gallic acid, tannic acid, BHA, catechin, quercetin, rutin and trolox) were carried out using the CRAC assay. The results showed a satisfactory correlation with those reported in the literature using other more complex assays and these studies were then applied to a set of industrialized fruit juices showing maximum values almost one order of magnitude higher than that of the reference compound (trolox) and following the antioxidant capacity sequence: cashew>guava>grape>mango>orange>passion fruit. Considering that the local \"cachaça\" industry is looking for alternative woods to the use of oak barrels, CRAC assays were carried out using four ethanol extracts of Brazilian woods [Pequi (Caryocar brasiliense), Imbuia (Octea porosa), Cabreúva (Myrocarpus frondosus) e Cabreúva-vermelha (Myroxylon balsamum)] as well as an Oak (Quercus sp) extract, for comparison. The results indicate an increasing antioxidant capacity in the order presented above and, although the best sample (Cabreúva-vermelha) has only 60% of the capacity shown by oak, its local availability and price makes it interesting for further research. A comparative evaluation of the results obtained using the CRAC and the DPPH assays was carried out for methanol extracts of sugar cane juice and passion fruit pulp. That comparison revealed a quantitative difference between the assay values but the hierarchy was maintained for each set of results. Such effect was attributed to differences in the prevailing mechanism for radical deactivation, as well as, the experimental conditions used for each assay. The correlation between structure and antioxidant activity of model flavonoid molecules under investigation was related to the presence of certain groups in the diphenilpyrene structure. The activity hierarchy for them was established as: OH(C2´C4´) > OH(C4´) ~ OH(C3´C4´) > C2=C3 + 4-oxo > OH(C3,C5) + 4-oxo > OH(C3) + 4-oxo > OH(C5) + 4-oxo > OH(C3,C5). The complex formation between flavonoids and metal ions, such as Fe2+, has a strong effect on the antioxidant capacity and CRAC assay showed that for morin, quercetin and fisetin the increase was 15.3, 31.8 and 27.9%, respectively. On the other hand, for catechin and chrysin the increase was only 1.8 and 7.8%, respectively. These increases were related to the presence of, at least, one of three types of active sites in the polyphenolic molecule that can interact with metal ions. All these findings confirm that the CRAC assay is simple and convenient tool for the determination of the antioxidant capacity of a variety of practical systems and model molecules.

antioxidant capacity

capacidade antioxidante

chronoamperometry

CRAC assay

cronoamperometria

ensaio CRAC

Caracterização do fruto de cambuci (Campomanesia phaea O. Berg.) e efeito da destanização sobre o potencial funcional in vitro / Characterization of the cambuci fruit (Campomanesia phaea O. Berg.) and deastringency effect on the in vitro functional potential

Sanches, Maria Cecilia Rocha

10 June 2013

A espécie Campomanesia phaea (O. Berg.) Landrum é popularmente conhecida como \"cambuci\". É uma das diversas espécies brasileiras de Myrtaceae com fruto comestível e ocorre nos estados de Minas Gerais e São Paulo, principalmente na Serra do Mar. Os frutos possuem intenso aroma agradável e são importantes fontes de compostos fenólicos. Apesar do excelente sabor e aroma do cambuci, a alta adstringência dos frutos, devido ao elevado conteúdo de taninos, reduz a sua aceitabilidade e aplicabilidade na indústria alimentícia. Uma maneira eficaz para remoção da adstringência é submeter o fruto a um processo de destanização, tal como atualmente utilizado para o caqui. O objetivo deste trabalho foi avaliar a variabilidade dos frutos provenientes de uma mesma região e de diferentes regiões, caracterizar frutos em diferentes estádios de maturação, avaliar a eficiência de tratamentos de destanização e determinar o efeito da destanização sobre o potencial funcional, através da determinação do teor e perfil de compostos fenólicos, capacidade antioxidante in vitro e inibição das enzimas do metabolismo de carboidratos. Os tratamentos testados foram: câmaras de etileno, câmara de etanol, ambiente anóxico, etanol no cálice e imersão em etanol. Os resultados mostram que frutos de uma mesma localidade apresentam variações no tamanho e na acidez. Frutos de diferentes regiões apresentaram variação significativa nos teores de fenólicos totais, minerais e na capacidade antioxidante. Com a maturação não foi observado grande variação no teor de sólidos solúveis totais e nem na acidez, porém o conteúdo de fenólicos decresce do estádio mais jovem para o mais maduro. Os processos de destanização com vapor e imersão em etanol foram os mais eficientes na redução do conteúdo de taninos, no entanto esses processos reduziram a capacidade antioxidante e a capacidade de inibição das enzimas α-amilase e α-glicosidase dos frutos. / The specie Campomanesia phaea (O. Berg.) Landrum is popularly known as \"cambuci\". It is one of several Brazilian species of Myrtaceae with edible fruit and occurs in the states of Minas Gerais and São Paulo, especially in the mountains of the sea. The fruits have an intense aroma and are important sources of phenolic compounds. Despite the excellent flavor and aroma of cambuci, high astringency of the fruit, due to the high tannin content, reduces its acceptability and applicability in the food industry. An effective way to astringency removal is to submit the fruit to a deastringency process, as currently used for the persimmon. The aim of this study was to evaluate the variability of the fruits from the same region and from different regions, characterize fruits in different maturation stages, evaluate the efficiency of treatments to astringency removal, and determine the effect of astringency removal about the functional potential, by determining the content and profile of phenolic compounds, antioxidant capacity, and in vitro inhibition of enzymes of carbohydrate metabolism. Treatments tested for removing the astringency were: ethylene chamber, ethanol chamber, anoxic environment, ethanol in the cup, and immersion in ethanol. The results showed that fruit in the same locality exhibit variations in size and acidity. Fruits from different regions showed significant variation in levels of total phenolics, minerals and antioxidant capacity. During maturation it was not observed a wide variation in the content of total soluble solids and acidity, but the phenolic content decreased from the younger stage to the more mature stage. The processes of detannization with ethanol steam and dipped in ethanol were the most effective in reducing the tannin content, however these processes led to reduced antioxidant capacity and capacity of inhibition of the enzymes α-amylase and α-glucosidase in fruits.

Antioxidant (Capacity)

Antioxidante (Capacidade)

Astringency removal

Cambuci

Cambuci

Remoção da adstringência

Desenvolvimento e aplicação de um novo ensaio para a determinação eletroquímica da capacidade antioxidante de compostos modelo e de matrizes complexas / Development and application of a new assay for the electrochemical determination of the antioxidant capacity of model compounds and of complex matrices

Rafael de Queiroz Ferreira

22 July 2009

Este trabalho descreve o desenvolvimento e aplicações práticas de uma nova e simples metodologia eletroquímica para a determinação da capacidade antioxidante de moléculas modelo específicas e/ou algumas amostras complexas de alimentos normalmente consumidas no Brasil. Outros sistemas de interesse teórico ou tecnológico também foram investigados. O método se baseia no uso de uma quantidade conhecida de um íon inorgânico como oxidante e na determinação cronoamperométrica de sua concentração remanescente após reação com as espécies antioxidantes de interesse. Contudo, testes iniciais para diferentes marcas comerciais de sucos de laranjas usando Fe3+ como oxidante (ensaio FRAP modificado), só obtiveram êxito quando o antioxidante apresenta um comportamento eletroquímico totalmente irreversível como, por exemplo, o ácido ascórbico. Para superar esse problema, o ensaio foi então desenvolvido usando o Ce4+ como oxidante (ensaio CRAC) uma vez que sua redução após reação pode ser realizada em 0,8 V vs Ag/AgCl, uma região de potencial na qual não ocorre a redução das espécies formadas pela oxidação reversível ou quase reversível do antioxidante. Devido ao elevado potencial anódico requerido quando o Ce4+ é usado, foi necessário um filme de diamante dopado com boro como eletrodo de trabalho. Após uma rigorosa caracterização do sistema eletroquímico, foram realizadas determinações da capacidade antioxidante de oito compostos padrões (ácido ascórbico, ácido gálico, ácido tânico, BHA, catequina, quercetina, rutina e trolox), usando o ensaio CRAC. Os resultados mostraram uma correlação satisfatória com ensaios mais complexos reportados na literatura e foram aplicados em um conjunto de sucos de frutas industrializados, mostrando valores máximos com quase uma ordem de grandeza superior ao apresentado pelo composto de referência (trolox), com a seguinte seqüência de capacidade antioxidante: caju > goiaba > uva > manga > laranja > maracujá. Considerando a busca da indústria local de \"cachaça\" por madeiras alternativas em contrapartida aos tonéis de carvalho, o ensaio CRAC foi realizado usando quatro extratos etanólicos de madeiras brasileiras [Pequi (Caryocar brasiliense), Imbuia (Octea porosa), Cabreúva (Myrocarpus frondosus) e Cabreúva-vermelha (Myroxylon balsamum)] assim como um extrato de Carvalho (Quercus sp), para comparação. Os resultados indicaram um aumento na capacidade antioxidante na ordem apresentada acima e, apesar da melhor amostra (Cabreúva-vermelha) ter apenas 60% da capacidade antioxidante apresentada pelo carvalho, sua disponibilidade e preço despertam o interesse por pesquisas futuras. Uma avaliação comparativa dos resultados obtidos usando os ensaios CRAC e DPPH foi realizado para extratos metanólicos de cana-de-açúcar e polpa de maracujá. Essa comparação revelou uma diferença quantitativa entre os valores dos ensaios, porém, a hierarquia foi mantida para cada conjunto de resultado. Esse efeito foi atribuído às diferenças nos mecanismos dominantes para a desativação radicalar, bem como para as condições experimentais de cada ensaio. A correlação entre a estrutura e a atividade antioxidante de moléculas modelo de flavonóides sob investigação foi relatada devido à presença de certos grupos substituintes na estrutura de difenilpirano. A atividade hierárquica para tais grupos foi estabelecida como: OH(C2´C4´) > OH(C4´) ~ OH(C3´C4´) > C2=C3 + 4-oxo > OH(C3,C5) + 4-oxo > OH(C3) + 4-oxo > OH(C5) + 4-oxo > OH(C3,C5). A formação de complexos entre flavonóides e íons metálicos, tal como o Fe2+, tem um forte efeito sobre a capacidade antioxidante e o ensaio CRAC mostrou que para a morina, quercetina e fisetina, esse aumento foi de 15,3; 31,8 e 27,9%, respectivamente. Por outro lado, para a catequina e crisina, o aumento foi de apenas 1,8 e 7,8%, respectivamente. Esses aumentos foram relatados devido à presença de, pelo menos, um dos três tipos de sítios ativos na molécula polifenólica que interage com íons metálicos. Todos esses resultados confirmam que o ensaio CRAC é uma ferramenta simples e viável para a determinação da capacidade antioxidante de uma variedade de sistemas práticos e moléculas modelo. / This work describes the development and practical applications of a novel and simple electrochemical methodology for the determination of the antioxidant capacity of specific model molecules and/or some complex food samples currently consumed in Brazil. Other systems having either theoretical or technological interest were also investigated. The method is based on the use of a known amount of an inorganic ion as the oxidant and in the chronoamperometric determination of its remaining concentration after reaction with the chosen antioxidant species. However, initial tests for different commercial brands of orange juices using Fe3+ as the oxidant (modified FRAP assay) were only successful when the antioxidant has a totally irreversible electrochemical behavior as, for example, ascorbic acid. To overcome this problem, the assays were then performed using Ce4+ as the oxidant (the CRAC assay) since its reduction after reaction can be carried out at 0.8 V vs Ag/AgCl, a potential region where the reduction of species formed by the reversible or quasi-reversible oxidation of the antioxidant does not occur. Due to the high anodic potentials required when using Ce4+, it was necessary to have a boron-doped diamond film as the working electrode. After a rigorous characterization of the electrochemical systems, measurements of the antioxidant capacity of eight standard compounds (ascorbic acid, gallic acid, tannic acid, BHA, catechin, quercetin, rutin and trolox) were carried out using the CRAC assay. The results showed a satisfactory correlation with those reported in the literature using other more complex assays and these studies were then applied to a set of industrialized fruit juices showing maximum values almost one order of magnitude higher than that of the reference compound (trolox) and following the antioxidant capacity sequence: cashew>guava>grape>mango>orange>passion fruit. Considering that the local \"cachaça\" industry is looking for alternative woods to the use of oak barrels, CRAC assays were carried out using four ethanol extracts of Brazilian woods [Pequi (Caryocar brasiliense), Imbuia (Octea porosa), Cabreúva (Myrocarpus frondosus) e Cabreúva-vermelha (Myroxylon balsamum)] as well as an Oak (Quercus sp) extract, for comparison. The results indicate an increasing antioxidant capacity in the order presented above and, although the best sample (Cabreúva-vermelha) has only 60% of the capacity shown by oak, its local availability and price makes it interesting for further research. A comparative evaluation of the results obtained using the CRAC and the DPPH assays was carried out for methanol extracts of sugar cane juice and passion fruit pulp. That comparison revealed a quantitative difference between the assay values but the hierarchy was maintained for each set of results. Such effect was attributed to differences in the prevailing mechanism for radical deactivation, as well as, the experimental conditions used for each assay. The correlation between structure and antioxidant activity of model flavonoid molecules under investigation was related to the presence of certain groups in the diphenilpyrene structure. The activity hierarchy for them was established as: OH(C2´C4´) > OH(C4´) ~ OH(C3´C4´) > C2=C3 + 4-oxo > OH(C3,C5) + 4-oxo > OH(C3) + 4-oxo > OH(C5) + 4-oxo > OH(C3,C5). The complex formation between flavonoids and metal ions, such as Fe2+, has a strong effect on the antioxidant capacity and CRAC assay showed that for morin, quercetin and fisetin the increase was 15.3, 31.8 and 27.9%, respectively. On the other hand, for catechin and chrysin the increase was only 1.8 and 7.8%, respectively. These increases were related to the presence of, at least, one of three types of active sites in the polyphenolic molecule that can interact with metal ions. All these findings confirm that the CRAC assay is simple and convenient tool for the determination of the antioxidant capacity of a variety of practical systems and model molecules.

capacidade antioxidante

cronoamperometria

ensaio CRAC

antioxidant capacity

chronoamperometry

CRAC assay

Polyphenols, ascorbate and antioxidant capacity of the Kei-apple (Dovyalis caffra) / Tersia de Beer

De Beer, Tersia

January 2006

Thesis (M.Sc. (Nutrition))--North-West University, Potchefstroom Campus, 2007.

Kei-apple

Polyphenols

Ascorbate

Antioxidant capacity

Gas chromatography mass-spectrometry

Dietary flavonoids as protectors from ascorbate-induced oxidative stress <i>in vivo</i>

Kang, Ester Mi Sun

25 April 2007

Flavonoids are of great interest for their antioxidant and health-promoting activities. Ascorbate (vitamin C) has antioxidant activities but also sometimes displays pro-oxidant activities <i>in vitro</i> and reportedly <i>in vivo</i>. This research investigated to what extent flavonoids moderate oxidative stress from vitamin C <i>in vivo</i>.<p>Dietary experiments were conducted in two phases using adult male Wistar rats. First, all animals were maintained for two weeks on a control flavonoid-free diet with the dietary requirement (27 IU) of vitamin E/kg diet. In the subsequent four weeks, the animals were treated in four groups (8 rats/group), being fed the following diets: flavonoid-free control (C), ascorbate-supplemented (7.55 mmol/kg diet) (A), flavonoid-supplemented (2.67 mmol/kg diet) (F) and flavonoids (2.67 mmol/kg diet) plus ascorbate (7.55 mmol/kg diet)-supplemented (T). Measurements were done on in vivo biomarkers of oxidative stress, tissue antioxidants and on tissue in vitro susceptibility to oxidative stress.<p>In the combined feeding of ascorbate plus flavonoids, endogenous thiobarbituric acid reactive substances (TBARS) increased in liver by 114%. No effects of dietary ascorbate or flavonoids were seen on endogenous TBARS in brain or heart, or on plasma thiols or erythrocyte fragility.<p><i>In vitro</i>, the susceptibility to TBARS formation of liver homogenate (incubated for 60 min at 37ºC in air) showed a significant 60% increase in ascorbate-fed animals compared to control, but no increase in animals fed ascorbate plus flavonoids, suggesting that the additional feeding of flavonoids helped to prevent the increase produced by ascorbate-feeding. Incubation of liver mitochondria with 300 µM ascorbate in vitro produced a large (2-7 fold) increase in TBARS, but there was no difference among mitochondria from the different feeding groups.<p>The ability of flavonoid-feeding in protecting against oxidative stress from ascorbate in vivo could not be demonstrated in this study, even showing pro-oxidant effects of flavonoids in combination with ascorbate in liver. However, in vitro tests in liver suggest a protective effect of flavonoid-feeding against susceptibility to oxidative stress from ascorbate. Further investigations are needed in order to resolve the differences observed in vitro and in vivo and to determine the endogenous effects of specific flavonoids under ascorbate-induced oxidative stress.

polyphenols

red blood cell hemolysis

total antioxidant capacity

reactive species

Dietary flavonoids as protectors from ascorbate-induced oxidative stress <i>in vivo</i>

Kang, Ester Mi Sun

25 April 2007

Flavonoids are of great interest for their antioxidant and health-promoting activities. Ascorbate (vitamin C) has antioxidant activities but also sometimes displays pro-oxidant activities <i>in vitro</i> and reportedly <i>in vivo</i>. This research investigated to what extent flavonoids moderate oxidative stress from vitamin C <i>in vivo</i>.<p>Dietary experiments were conducted in two phases using adult male Wistar rats. First, all animals were maintained for two weeks on a control flavonoid-free diet with the dietary requirement (27 IU) of vitamin E/kg diet. In the subsequent four weeks, the animals were treated in four groups (8 rats/group), being fed the following diets: flavonoid-free control (C), ascorbate-supplemented (7.55 mmol/kg diet) (A), flavonoid-supplemented (2.67 mmol/kg diet) (F) and flavonoids (2.67 mmol/kg diet) plus ascorbate (7.55 mmol/kg diet)-supplemented (T). Measurements were done on in vivo biomarkers of oxidative stress, tissue antioxidants and on tissue in vitro susceptibility to oxidative stress.<p>In the combined feeding of ascorbate plus flavonoids, endogenous thiobarbituric acid reactive substances (TBARS) increased in liver by 114%. No effects of dietary ascorbate or flavonoids were seen on endogenous TBARS in brain or heart, or on plasma thiols or erythrocyte fragility.<p><i>In vitro</i>, the susceptibility to TBARS formation of liver homogenate (incubated for 60 min at 37ºC in air) showed a significant 60% increase in ascorbate-fed animals compared to control, but no increase in animals fed ascorbate plus flavonoids, suggesting that the additional feeding of flavonoids helped to prevent the increase produced by ascorbate-feeding. Incubation of liver mitochondria with 300 µM ascorbate in vitro produced a large (2-7 fold) increase in TBARS, but there was no difference among mitochondria from the different feeding groups.<p>The ability of flavonoid-feeding in protecting against oxidative stress from ascorbate in vivo could not be demonstrated in this study, even showing pro-oxidant effects of flavonoids in combination with ascorbate in liver. However, in vitro tests in liver suggest a protective effect of flavonoid-feeding against susceptibility to oxidative stress from ascorbate. Further investigations are needed in order to resolve the differences observed in vitro and in vivo and to determine the endogenous effects of specific flavonoids under ascorbate-induced oxidative stress.

polyphenols

red blood cell hemolysis

total antioxidant capacity

reactive species

Polyphenols, ascorbate and antioxidant capacity of the Kei-apple (Dovyalis caffra) / Tersia de Beer

De Beer, Tersia

January 2006

There is a close relationship between the susceptibility to disease and nutritional state, in the sense that an adequate diet enhances resistance to disease. There is an increasing interest in this beneficial relationship among scientists, food manufacturers and consumers. The trend is moving towards functional foods and their specific health benefits. The results of numerous epidemiological studies and recent clinical trials provide consistent evidence that diets rich in fruits and vegetables can reduce the risk of chronic diseases. These protective effects are mediated through multiple groups of beneficial nutrients contained in the fruits and vegetables, one of these being polyphenol antioxidants. The intake of the polyphenols plays an important role in the reduction and prevention of coronary heart disease (CHD), cardiovascular disease and cancer, as a consequence of their associated antioxidant properties. Fruits contain an array of polyphenols with antioxidant capacity. Polyphenols may be classified in two broad groups namely: flavonoids and non-flavonoids. Flavonoid subgroups in fruits are further grouped as catechins, anthocyanins, procyanidins and flavonol among others. Phenolic acids occur as hydroxylated derivatives of benzoic acid and cinnarnic acid, and are classified as non-flavonoids. Polyphenols have redox properties allowing them to act as reducing agents, hydrogen donators and singlet oxygen quenchers, and thus contribute to the antioxidant capacity of fruits and vegetables. Because of the numerous beneficial effects attributed to these antioxidants, there is renewed interest in finding vegetal species with high phenolic content and relevant biological activities. In view of the importance of these substances towards health and food chemistry, this study will focus on the polyphenol and Vitamin C characterisation and quantification of an indigenous South African fruit, the Kei-apple (Dovyalis cafra), thought to have antioxidant properties. Due to the fact that polyphenol content influences the colour, taste and possible health benefits of the fruit / processed food product, this study will supply valuable information to industry in choosing the best fruit processing methods to attain the desired end product. The exploitation of indigenous South African fruits (Marula and Kei-apple) is receiving increasing prominence, not only due to their health benefits, but also the opportunities these present to rural based economics. Furthermore, this research will serve as a platform for further research on the Kei-apple and other indigenous South African fruits with possible health benefits. Aims: The overall aim of this study is the quantification and characterisation of various nutritionally important antioxidants (polyphenols and ascorbate) in the Kei-apple fruit in its entirety, as well as in its individual fruit components (peel, flesh and seeds). In addition, the total antioxidant capacity of the entire fruit and the various fruit components will be determined in the unfractionated and fractionated fruit extracts. Gas chromatography coupled mass spectrometry (GC-MS) characterisation of the individual polyphenol components will also be analyzed in order to speculate on possible specific health benefits which the Kei-apple may possess. Methods: The study was designed to ensure that a representative fruit sample was collected. Approximately 100 kg Kei-apples were picked in the month of November 2004 from the Bloemhof area in South Africa. A sample of 50 fruits was rinsed and separated into the various components (peel, flesh and seeds). An additional 50 fruits were randomly selected, cleaned and used in their entirety for data representative of the entire fruit. The sample extracts were prepared, after being grounded and lyophilized, by a method described by Eihkonen et al. (1999) using 70% aqueous acetone. The C18-fractionation on the fruit and separated fruit components resulted in four fractions containing (1) phenolic acids; (2) procyanidins, catechins and anthocyanin monomers; (3) flavonols and (4) anthocyanin polymers. The total polyphenol content of the fruit and fruit components as well as the above mentioned C18-fractions were determined by Folin-Ciocalteu's method (Singleton & Rossi, 1965). Both free and total ascorbate concentrations in these samples were determined as described by Beutler (1984), in addition to total sugar content of these via standard methods. Apart from their nutritional interest, both these measurements are necessary for the correction of the total polyphenol concentrations. The total antioxidant capacity of the entire fruit and various fruit components was determined by measuring the oxygen radical absorbance capacity (ORAC) and ferric reducing antioxidant power (FRAP) of the unfractionated and fractionated extracts. Using GC-MS analysis, the various individual polyhenol compounds contributing to the total polyphenol content of the Kei-apple was separated, identified and quantified. This quantitative data was captured and statistically analysed. The analysis of variation was performed using the Tukey Honest Significant Difference test for post-hoc comparison. ORAC, FRAP and polyphenol Pearson correlation analyses were performed using Statistics (Statsoft Inc., Tulsa, Oklahoma, USA) with significance set at P ≤ 0.05. Results and discussion: This study determined the presence of various nutritionally important antioxidants (polyphenols and ascorbate), the total antioxidant capacity in the entire fruit as well as in the individual fruit components (peel, flesh and seeds) and their polyphenol sub group fractions. Total phenol content: The Kei-apple, in its entirety, has a polyphenol concentration of 943 ± 20.3 mg GAE/100g dry weight. Comparison of the individual fruit components showed the seeds to have the highest total polyphenol concentration with 1990 ± 31.3 mg GAE/100g dry weight, followed by that of the peel, 1126 ± 45.8 mg GAE/100g dry weight and then that of the flesh, 521 ± 1.01 mg GAE/100g dry weight. Total, L-ascorbic (ASC) and L-dehydroascobic (DHA) concentration: The total ascorbate of Kei-apple fruit is 517 ± 0.92 mg/100g dry weight. In contrast to the polyphenol content, the flesh of the Kei-apple had significantly the highest concentration of total ascorbate 778 ± 1.20 mg/100g dry weight, Gascorbic 241 ± 21.0 mg/100g dry weight, as well as Gdehydroascobic 537 ± 22.2 mg/100g dry weight. The ratio of Lascorbic acidltotal ascorbate for the flesh, entire fruit, peel and seed is 0.31,0.43,0.49,0.95, respectively, indicating the seeds are the most stable source of biologically active Vitamin C, with 95% of the total ascorbate occurring as G ascorbate. This is also in line with the total polyphenol content of these components, confirming a polyphenol sparing effect on ascorbate. C18-fractionation extracts: Solid phase (C18) fractionation of the Kei-apple fruit and fruit components showed that the fruit, peels and seeds consist predominantly of phenolic acids, followed by procyanidin, catechin and anthocyanin monomers and thereafter varying amounts of anthocyanin polymers and flavonols. Antioxidant capacity: The antioxidant capacity of the entire fruit and individual fruit components as determined by ORAC, (r=0.76) and FRAP, (r=0.95) significantly correlated with the total polyphenol content, as well as to each other (r=0.88), indicating both to be good predictors of antioxidant capacity. GC-MS polyphenol characterisation of the Kei-apple: Caffeic acid and hydro-p-coumaric acid were seen to be the phenolic acids occurring in the highest concentrations in the Kei-apple fruit. The majority of these are concentrated in the flesh and in the case of caffeic acid, also in the peel. The order of predominance of other major non-flavonoid components in the whole fruit analysis are m-hydroxybenzoic acid > p-hydroxyphenyl acetic acid > 3-methoxy-4- hydroxyphenylpropionic acid > p-coumaric acid. The peel of the Kei-apple, apart from caffeic acid, has exceptionally high concentrations of ferulic acid and also serves as a source of protocatechuic acid. Syringic acid was most prominent in the seeds. Although the total flavonoid concentration in the Kei-apple was low, taxifolin and catechin were identified and the seeds almost entirely accounting for these. Conclusion: From this study it was concluded the Kei-apple is a rich source of antioxidant compounds (polyphenols and ascorbate), with a strong antioxidant capacity, and hence may be associated with health promotion properties, particularly in the prevention of cancer, cardiovascular disease, and neurodegeneration. Additionally, due to the increased scientific and commercial interest in this fruit, it is essential to take into consideration the various factors (agronomic, genomic, pre- and post harvest condition and processing) and tissues. This might affect the chemical composition of the final marketed product, which may play a significant role in determining the polyphenol and ascorbate composition and bioactivity of these compounds during food processing procedures. Hence, the polyphenol composition of the various fruit components should be taken into consideration when selecting a method of fruit processing into the desired end product. / Thesis (M.Sc. (Nutrition))--North-West University, Potchefstroom Campus, 2007.

Kei-apple

Polyphenols

Ascorbate

Antioxidant capacity

Gas chromatography mass-spectrometry

Polyphenols, ascorbate and antioxidant capacity of the Kei-apple (Dovyalis caffra) / Tersia de Beer

De Beer, Tersia

January 2006

There is a close relationship between the susceptibility to disease and nutritional state, in the sense that an adequate diet enhances resistance to disease. There is an increasing interest in this beneficial relationship among scientists, food manufacturers and consumers. The trend is moving towards functional foods and their specific health benefits. The results of numerous epidemiological studies and recent clinical trials provide consistent evidence that diets rich in fruits and vegetables can reduce the risk of chronic diseases. These protective effects are mediated through multiple groups of beneficial nutrients contained in the fruits and vegetables, one of these being polyphenol antioxidants. The intake of the polyphenols plays an important role in the reduction and prevention of coronary heart disease (CHD), cardiovascular disease and cancer, as a consequence of their associated antioxidant properties. Fruits contain an array of polyphenols with antioxidant capacity. Polyphenols may be classified in two broad groups namely: flavonoids and non-flavonoids. Flavonoid subgroups in fruits are further grouped as catechins, anthocyanins, procyanidins and flavonol among others. Phenolic acids occur as hydroxylated derivatives of benzoic acid and cinnarnic acid, and are classified as non-flavonoids. Polyphenols have redox properties allowing them to act as reducing agents, hydrogen donators and singlet oxygen quenchers, and thus contribute to the antioxidant capacity of fruits and vegetables. Because of the numerous beneficial effects attributed to these antioxidants, there is renewed interest in finding vegetal species with high phenolic content and relevant biological activities. In view of the importance of these substances towards health and food chemistry, this study will focus on the polyphenol and Vitamin C characterisation and quantification of an indigenous South African fruit, the Kei-apple (Dovyalis cafra), thought to have antioxidant properties. Due to the fact that polyphenol content influences the colour, taste and possible health benefits of the fruit / processed food product, this study will supply valuable information to industry in choosing the best fruit processing methods to attain the desired end product. The exploitation of indigenous South African fruits (Marula and Kei-apple) is receiving increasing prominence, not only due to their health benefits, but also the opportunities these present to rural based economics. Furthermore, this research will serve as a platform for further research on the Kei-apple and other indigenous South African fruits with possible health benefits. Aims: The overall aim of this study is the quantification and characterisation of various nutritionally important antioxidants (polyphenols and ascorbate) in the Kei-apple fruit in its entirety, as well as in its individual fruit components (peel, flesh and seeds). In addition, the total antioxidant capacity of the entire fruit and the various fruit components will be determined in the unfractionated and fractionated fruit extracts. Gas chromatography coupled mass spectrometry (GC-MS) characterisation of the individual polyphenol components will also be analyzed in order to speculate on possible specific health benefits which the Kei-apple may possess. Methods: The study was designed to ensure that a representative fruit sample was collected. Approximately 100 kg Kei-apples were picked in the month of November 2004 from the Bloemhof area in South Africa. A sample of 50 fruits was rinsed and separated into the various components (peel, flesh and seeds). An additional 50 fruits were randomly selected, cleaned and used in their entirety for data representative of the entire fruit. The sample extracts were prepared, after being grounded and lyophilized, by a method described by Eihkonen et al. (1999) using 70% aqueous acetone. The C18-fractionation on the fruit and separated fruit components resulted in four fractions containing (1) phenolic acids; (2) procyanidins, catechins and anthocyanin monomers; (3) flavonols and (4) anthocyanin polymers. The total polyphenol content of the fruit and fruit components as well as the above mentioned C18-fractions were determined by Folin-Ciocalteu's method (Singleton & Rossi, 1965). Both free and total ascorbate concentrations in these samples were determined as described by Beutler (1984), in addition to total sugar content of these via standard methods. Apart from their nutritional interest, both these measurements are necessary for the correction of the total polyphenol concentrations. The total antioxidant capacity of the entire fruit and various fruit components was determined by measuring the oxygen radical absorbance capacity (ORAC) and ferric reducing antioxidant power (FRAP) of the unfractionated and fractionated extracts. Using GC-MS analysis, the various individual polyhenol compounds contributing to the total polyphenol content of the Kei-apple was separated, identified and quantified. This quantitative data was captured and statistically analysed. The analysis of variation was performed using the Tukey Honest Significant Difference test for post-hoc comparison. ORAC, FRAP and polyphenol Pearson correlation analyses were performed using Statistics (Statsoft Inc., Tulsa, Oklahoma, USA) with significance set at P ≤ 0.05. Results and discussion: This study determined the presence of various nutritionally important antioxidants (polyphenols and ascorbate), the total antioxidant capacity in the entire fruit as well as in the individual fruit components (peel, flesh and seeds) and their polyphenol sub group fractions. Total phenol content: The Kei-apple, in its entirety, has a polyphenol concentration of 943 ± 20.3 mg GAE/100g dry weight. Comparison of the individual fruit components showed the seeds to have the highest total polyphenol concentration with 1990 ± 31.3 mg GAE/100g dry weight, followed by that of the peel, 1126 ± 45.8 mg GAE/100g dry weight and then that of the flesh, 521 ± 1.01 mg GAE/100g dry weight. Total, L-ascorbic (ASC) and L-dehydroascobic (DHA) concentration: The total ascorbate of Kei-apple fruit is 517 ± 0.92 mg/100g dry weight. In contrast to the polyphenol content, the flesh of the Kei-apple had significantly the highest concentration of total ascorbate 778 ± 1.20 mg/100g dry weight, Gascorbic 241 ± 21.0 mg/100g dry weight, as well as Gdehydroascobic 537 ± 22.2 mg/100g dry weight. The ratio of Lascorbic acidltotal ascorbate for the flesh, entire fruit, peel and seed is 0.31,0.43,0.49,0.95, respectively, indicating the seeds are the most stable source of biologically active Vitamin C, with 95% of the total ascorbate occurring as G ascorbate. This is also in line with the total polyphenol content of these components, confirming a polyphenol sparing effect on ascorbate. C18-fractionation extracts: Solid phase (C18) fractionation of the Kei-apple fruit and fruit components showed that the fruit, peels and seeds consist predominantly of phenolic acids, followed by procyanidin, catechin and anthocyanin monomers and thereafter varying amounts of anthocyanin polymers and flavonols. Antioxidant capacity: The antioxidant capacity of the entire fruit and individual fruit components as determined by ORAC, (r=0.76) and FRAP, (r=0.95) significantly correlated with the total polyphenol content, as well as to each other (r=0.88), indicating both to be good predictors of antioxidant capacity. GC-MS polyphenol characterisation of the Kei-apple: Caffeic acid and hydro-p-coumaric acid were seen to be the phenolic acids occurring in the highest concentrations in the Kei-apple fruit. The majority of these are concentrated in the flesh and in the case of caffeic acid, also in the peel. The order of predominance of other major non-flavonoid components in the whole fruit analysis are m-hydroxybenzoic acid > p-hydroxyphenyl acetic acid > 3-methoxy-4- hydroxyphenylpropionic acid > p-coumaric acid. The peel of the Kei-apple, apart from caffeic acid, has exceptionally high concentrations of ferulic acid and also serves as a source of protocatechuic acid. Syringic acid was most prominent in the seeds. Although the total flavonoid concentration in the Kei-apple was low, taxifolin and catechin were identified and the seeds almost entirely accounting for these. Conclusion: From this study it was concluded the Kei-apple is a rich source of antioxidant compounds (polyphenols and ascorbate), with a strong antioxidant capacity, and hence may be associated with health promotion properties, particularly in the prevention of cancer, cardiovascular disease, and neurodegeneration. Additionally, due to the increased scientific and commercial interest in this fruit, it is essential to take into consideration the various factors (agronomic, genomic, pre- and post harvest condition and processing) and tissues. This might affect the chemical composition of the final marketed product, which may play a significant role in determining the polyphenol and ascorbate composition and bioactivity of these compounds during food processing procedures. Hence, the polyphenol composition of the various fruit components should be taken into consideration when selecting a method of fruit processing into the desired end product. / Thesis (M.Sc. (Nutrition))--North-West University, Potchefstroom Campus, 2007.

Kei-apple

Polyphenols

Ascorbate

Antioxidant capacity

Gas chromatography mass-spectrometry